RU175376U1 - Composite stand - Google Patents

Abstract

The utility model relates to the field of mast structure. A composite stand is an elongated tubular shape made of a composite material, a hollow body made by winding a reinforcing material using a binder and having a layered cross-sectional structure. In this case, a reinforcing filler is used, located between the winding layers of the tubular shape of the body. This reinforcing filler is placed in a binder. 1 ill.

Description

The utility model relates to the field of mast construction and relates to the construction of composite racks, in particular for power lines (power lines), lighting poles and antenna masts.

In recent years, overhead power line poles, lighting poles and antenna masts with composite stands have been intensively developed.

Composite towers of overhead power lines are a relatively new type of mast structures. Their experience at the present time is still small, but the characteristics of modern composite materials give the supports of this type a number of properties unusual for other types of supports, which are of particular interest from the point of view of reducing installation costs and increasing the operational reliability of overhead power lines.

A composite is called an inhomogeneous continuous material consisting of two or more functionally different components that have clear boundaries, while the properties of the composite are determined not only and not so much by the properties of the components themselves, but by their spatial arrangement and nature of the interaction. Currently, the terms “composite” and “composite material” are used more narrowly in relation to only reinforced polymer composite materials. As the reinforcing fillers currently distributed (in descending order): glass, basalt, organic and carbon fiber. Organic and carbon fiber have a very high cost and large-capacity bulk products are not used.

Currently, the following production technologies are used for the production of composite racks: pultrusion, filament winding, infusion. Pultrusion is as follows: the finished fiberglass is impregnated with a special binder, the resulting product is given the necessary shape and the product is pulled through the die, followed by cutting it into pieces of a certain length. And filament processing consists of the following stages: the prepared raw materials (fibers) are connected using a matrix substrate, wound them on a rotationally symmetric core, then they are cooled and the workpieces are used for their intended purpose.

Thus, a stand of an overhead power line support is known, comprising a module made in the form of a hollow truncated cone made of a composite material based on a reinforcing filler impregnated with a binder, while the wall of the module has a variable thickness along its longitudinal axis (RU 162084, E04H 12/02, publ. May 27, 2016). Adopted as a prototype.

About this patent, the rack is made of a composite material of a given thickness, formed from fibers (threads) of a reinforcing filler, for example, glass roving, and a polymer binder during the wet winding process on a conical mandrel. As the polymeric binder, for example, an epoxy vinyl ester resin with additives (hardener and accelerator) can be used to improve the polymerization. And in order to increase the strength of the module with respect to mechanical stresses of various directions (compressive, tensile, tangential) arising in the wall of the module from external influences on the support of the power line support, the composite material is wound with cross-spiral laying of its layers at different angles with respect to longitudinal axis of the conical module.

Application of the method of winding with fiber allows you to make adjustments to the final mechanical properties of composite racks. This method is based on the formation of a fiberglass product by a continuous filament of fiberglass, which is impregnated with a binder and wound on a forming surface - a cylindrical or conical mandrel. This method is widely used in large-scale production of pipes, tanks and fittings. The procedure for manufacturing a fiberglass product by winding is as follows: a continuous roving, which is a reinforcing material for a future product, is fed to a rotating metal mandrel (template) at a certain angle. Roving threads are impregnated with a pre-prepared binder. If necessary, fillers such as quartz, chopped roving, aluminum oxide, etc. can be introduced into the wall of the pipe or container. After curing, the finished product is removed from the mandrel and subjected to machining: grinding of the ends, grooving of chamfers, etc.

The mandatory stage of the product manufacturing process by winding is the curing of the workpiece wound on the mandrel. In this case, the workpiece can be further sealed using vacuum or inflatable bags. High strength of products obtained by winding is achieved due to the oriented packing of the filler, its high content in the material of the product. With unidirectional laying, the volume content of fiberglass can reach 90%, and the tensile stress at the fiberglass is 30,000 kgf / cm ² , while for fiberglass - 50% with a fiberglass strength of no higher than 5000-7000 kgf / cm ² (tensile stress fiberglass with a non-oriented structure of the filler, obtained by spraying, is only 1000-1500 kgf / cm ² ).

The practice of applying the winding method to obtain composite stands shows that fillers, as components that affect the final mechanical properties of the product, are introduced separately as sprayed or applied to a laid layer of reinforcing material. This leads to the fact that the introduction of this deposited component into the body of the product structure in order to obtain a monolithic structure is carried out by tensioning the subsequent layers, recessing the filler particles into the binder in the layers themselves. Naturally, for the organization of a monostructure in the product, this product must be subjected to additional compaction. In addition, it is necessary to observe the process of uniform application of particles of quartz, chopped roving or aluminum oxide on the entire surface of the wound layers, which is quite problematic due to the fact that the body of the product is constantly rotating. Violation of the conditions of the technology can lead to an inhomogeneous monostructure of the body of the rack, in which individual zones will differ from each other in mechanical (strength) properties.

This utility model is aimed at achieving a technical result consisting in increasing operational durability by obtaining a monostructure of the rack body by reinforcing with a binder filled with fragmented glass, basalt or carbon fibers or nanotubes.

The specified technical result is achieved in that in a composite stand, which is an elongated tubular shape made of composite material, a hollow body made by winding a reinforcing material using a binder and having a layered structure along the cross section, as well as a reinforcing filler placed between the layers of the tubular shape winding body, the specified reinforcing filler is placed in a binder.

In this case, the reinforcing filler placed in the binder can be made in the form of fragmented glass and / or basalt and / or carbon fibers or nanotubes.

An elongated tubular shape made of a composite material may have a truncated cone shape.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This useful model is illustrated by an example of implementation, which, however, is not the only possible, but clearly demonstrates the possibility of achieving the desired technical result.

In FIG. 1 - shows the installation for wet winding of reinforcing material on a template for the manufacture of composite racks.

According to this utility model, the construction of a composite stand reinforced with a filler that is added to the binder is considered. Such composite racks are used as poles of power lines.

In order to reduce the flexibility of composite racks and increase their bearing capacity, it is proposed to perform them volume-reinforced. Volumetric reinforcement is performed by filling the binder with fragmented glass and / or basalt and / or carbon fibers or nanotubes. Volumetric reinforcement can be performed as separate fillers, and their combinations. Volumetric reinforcement is carried out by mixing the above fillers in a binder, which is subsequently used in the manufacture of composite stands. In addition to reducing flexibility, volume reinforcement will also lead to an increase in the bearing capacity of the uprights.

Thus, in the general case, within the framework of this utility model, a composite stand is considered, which is an elongated tubular shape made of composite material, made by winding a polymer reinforcing material using a binder and having a layered structure along the cross section, as well as a reinforcing filler placed between the layers of the winding tubular body shape. Moreover, the specified reinforcing filler is placed in the volume of the binder. The composite strut may be in the form of a truncated cone or cylinder.

Winding is the process of manufacturing high-strength reinforced products, the shape of which is determined by the rotation of arbitrary generators. With this method, the reinforcing material 1 (thread, tape, tow or fabric) is laid along a predetermined path onto a rotating mandrel 2 (template), which carries the internal geometry of the product. Almost any continuous reinforcing material is suitable for winding. Special mechanisms, for example, trolley 3, which move at a speed synchronized with the rotation of the mandrel, control the angle of winding and the location of the reinforcing material. It can be wrapped around the mandrel in the form of adjacent strips or in some kind of repeating pattern until the mandrel surface is completely covered. Successive layers 4 are applied at the same or different winding angles until the desired thickness is achieved. The reinforcing material is supplied from the trolley 3 and passed through a bath 5 filled with a binder wetting the material 1. The wetted binder material through the pinch rollers 6 enters the mandrel and, when the latter rotates with a given tension, wraps on a previously laid layer of reinforcing material.

Since the winding process can be automated, it refers to technologically advanced processes in which it is possible to ensure equal strength of the structure of the rack due to the exception when winding caverns, air inclusions, etc. This speeds up the manufacturing process of the rack. In addition, during winding, foreign inserts such as reinforcing rods can be included in the composite structure, which subsequently, when wound with coating layers, become an organic part of the structure of the rack body.

The introduction of reinforcing particles into the composite structure leads to a change in the mechanical properties of the product by increasing its strength while reducing elasticity. In this case, elasticity is understood as the degree of deviation of one end of the rack body with respect to the fixed other end. Strengthening the composite with a filler reduces the elasticity and flexibility of a lengthy product while increasing strength. But it should be borne in mind that the use of a filler gives a corresponding result only if the filler particles must be uniform with the wound layers to obtain a homogenized structure of a uniform and evenly distributed composition. When using the loose method of laying the filler on a wound layer of material, the particles merge with the binder released on the surface of the wound layer and unevenly distributed heaps remain on this surface. Then these locally grouped particles are coated with the material of the next layer. A structure with a nonuniformly distributed filler is formed.

The problem of obtaining such a structure of a uniform and uniformly distributed composition in the framework of this utility model is solved due to the fact that the filler is mixed with a binder and evenly distributed over the volume of the binder. When winding "wet", the coating material is lubricated with such a combined binder, which leads to a uniform distribution of the binder and filler with it over the surface of the layers. This makes it possible to obtain a homogenized structure of a uniform and evenly distributed composition.

The need to obtain just such a structure in the body of the composite strut is due to the fact that between the molecules of the composite the same bonds are obtained both in height and in cross section at each height element. Only in this case, the load on the top of the rack will be uniformly perceived by the entire structure of the rack. If the conditions of identical intermolecular bonds are violated, then local volume zones will be formed in the structure of the body of the rack, in which there will be bonds of different magnitude and physical properties for tension / compression and torsion. This leads to the fact that the entire load will be perceived only by those volumetric zones in which these connections are least, that is, weaker. And volume zones with strengthened bonds (due to the filler) will either not participate in the deformation processes, or will turn on under critical stress conditions in weak bonds.

In this regard, such a rack design made by winding in which the reinforcing filler is in a mixed state in a binder has reduced flexibility and increased bearing capacity, and allows to reduce the deviation of the racks.

This utility model is industrially applicable and can be manufactured using modern technologies for manufacturing products from composites by winding.

Claims (2)

1. A composite stand, which is an elongated tubular hollow body having a layered cross-sectional structure, made by winding a reinforcing material impregnated with a binder, using a reinforcing filler, characterized in that nanotubes pre-mixed with the binder are used as filler. 2. Composite stand according to claim 1, characterized in that the elongated tubular hollow body is made in the form of a truncated cone.

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